ESTABLISHING THE RELIABILITY LEVEL OF MASONRY BEARING STRUCTURES BASED ON ITS COMPONENT STRENGTH ANALYSIS

Authors

  • D. Yermolenko National University “Yuri Kondratyuk Poltava Polytechnic”
  • I. Usenko National University “Yuri Kondratyuk Poltava Polytechnic”
  • D. Usenko National University “Yuri Kondratyuk Poltava Polytechnic”

DOI:

https://doi.org/10.33042/2522-1809-2024-1-182-74-81

Keywords:

reliability theory, reliability assessment, structural safety, stone structures, masonry strength

Abstract

The article discusses aspects related to assessing the reliability of masonry structures. The authors present methods for determining the compressive strength of masonry in existing structures, taking into account reliability theory. We also consider practical solutions for calculating the design strength of masonry, which may help to assess the safety of massive brick walls and pillars that act as core structural elements of existing buildings. Thus, walls and pillars operating in compression are vital elements of stone buildings and require special attention when analysing and assessing their strength. They carry enormous loads and are critical to the stability of the entire structure. There are cases when it may be hard to obtain safe samples for testing masonry mechanical performance, making the analysis of existing masonry structures difficult. However, building codes and methods provide specific methods for determining the strength of existing structures based on reliability theory. These methods assume uniformity of masonry with regularly spaced brick layers. Although such assumptions may simplify the analysis, they can still provide sufficiently accurate results for making decisions about the safety and reliability of the building. It is essential to consider all possible factors and limitations when using these methods to ensure a reliable assessment of the condition of masonry structures.

Stone materials are among the most traditional in various areas of construction production. Buildings with brick load-bearing walls represent the lion’s share of the existing housing development in Ukraine. Ensuring its high-quality operation and the safety of residents during the life cycle of such buildings are priority areas. However, changes occurring in the external environment and the state of regulatory support for construction production require a periodic return to the issues of assessing the load-bearing capacity of both previously erected building structures and those under design. Thus, lately, the territories with previously unusual force impacts on building structures, such as horizontal displacements of the base of the building, have significantly expanded. The reasons for this include seismic activity in certain regions of the country and the results of anthropogenic factors, particularly the areas with unstable soils. We should note that many buildings and structures are subject to external influence due to military operations on a large territory of Ukraine. So, in the event of a hit by warheads or the action of a blast wave, they generate new, non-typical, but dangerous effects on the load-bearing structures of the entire building.

Author Biographies

D. Yermolenko, National University “Yuri Kondratyuk Poltava Polytechnic”

Doctor of Technical Sciences, Professor at the Department of Highways, Geodesy and Land Management

I. Usenko, National University “Yuri Kondratyuk Poltava Polytechnic”

Candidate of Technical Sciences, Associate Professor at the Department of Building and Civil Engineering

D. Usenko, National University “Yuri Kondratyuk Poltava Polytechnic”

PhD, MPhys, Associate Professor at the Department of Chemistry and Physics

References

Usenko, D., Dovzhenko, O., Pohribnyi, V., & Zyma, O. (2020). Masonry strengthening under the combined action of vertical and horizontal forces. In F. Gatuingt, & J.-M. Torrenti (Eds.), Proceedings of the 2020 session of the 13th fib International PhD Symposium in Civil Engineering, 2020 (pp. 193‒199). fib (International Federation for Structural Concrete). https://phdsymp2020.sciencesconf.org/data/pages/Proceedings_phdsymp_2021.pdf#page=204

Dovzhenko, O., Pohribnyi, V., Usenko, V., & Usenko, D. (2021). The masonry calculation strength under the vertical and horizontal loads combined action by the variational method in the plasticity theory. Academic journal “Industrial Machine Building, Civil Engineering”, 2(57), 26‒31. https://journals.nupp.edu.ua/znp/article/view/2581/2477

Usenko, V., & Usenko, D. (2023). Masonry reliability under diagonal splitting. In A. Jankovska (Ed.), Science, technology and innovation in the modern world: scientific monograph (Chapter “Engineering sciences”, pp. 136‒159). Baltija Publishing. https://doi.org/10.30525/978-9934-26-364-4-6

Małyszko, L., & Bilko, P. (2009). Prediction of masonry strength taking into account theory of structural reliability. Civil Engineering and Building, 65(12), 681‒684 [in Polish]

Lumantarna, R., Biggs, D. T., Ingham, J. M. (2014). Uniaxial Compressive Strength and Stiffness of Field-Extracted and Laboratory-Constructed Masonry Prisms. Journal of Materials in Civil Engineering, 26(4), 567‒575. https://doi.org/10.1061/(ASCE)MT.1943-5533.0000731

Binda, L. (Ed.). (2008). Learning from Failure: Long-term Behaviour of Heavy Masonry Structures. WIT Press. https://archive.org/details/learningfromfail0000unse/mode/2up

Lumantarna, R., Dizhur, D., Derakhshan, H., & Ingham, J. (2010). Strength and stiffness of unreinforced masonry: Comparison between laboratory and field studies. In W. Jäger, B. Haseltine, & A. Fried (Eds.), Proceedings of the 8th International Masonry Conference (vol. 2, pp. 1171–1180). International Masonry Society. https://www.researchgate.net/publication/274700133

Matysek, P. (2014). Identification of compressive strength and deformability of brick masonry in existing buildings: monography. Cracow University of Technology Publishing House. https://repozytorium.biblos.pk.edu.pl/resources/25701 [in Polish]

Kirtschig, K. (1982). Masonry classes and their verification. VDI-Berichte, 438 [in German]

Schueremans, L. (2001). Probabilistic evaluation of structural unreinforced masonry [Doctoral dissertation, Catholic University of Leuven]. KU Leuven. https://bwk.kuleuven.be/mat/publications/phdthesis/2001-schueremans-ph-d.pdf [in English]

Downloads

Published

2024-04-05

How to Cite

Yermolenko, D., Usenko, I., & Usenko, D. (2024). ESTABLISHING THE RELIABILITY LEVEL OF MASONRY BEARING STRUCTURES BASED ON ITS COMPONENT STRENGTH ANALYSIS. Municipal Economy of Cities, 1(182), 74–81. https://doi.org/10.33042/2522-1809-2024-1-182-74-81

Issue

Vol. 1 No. 182 (2024): Series: Engineering science and architecture (to be updated)

Section

статьи

License

The authors who publish in this collection agree with the following terms:
• The authors reserve the right to authorship of their work and give the magazine the right to first publish this work under the terms of license CC BY-NC-ND 4.0 (with the Designation of Authorship - Non-Commercial - Without Derivatives 4.0 International), which allows others to freely distribute the published work with a mandatory reference to the authors of the original work and the first publication of the work in this magazine.
• Authors have the right to make independent extra-exclusive work agreements in the form in which they were published by this magazine (for example, posting work in an electronic repository of an institution or publishing as part of a monograph), provided that the link to the first publication of the work in this journal is maintained. .
• Journal policy allows and encourages the publication of manuscripts on the Internet (for example, in institutions' repositories or on personal websites), both before the publication of this manuscript and during its editorial work, as it contributes to the emergence of productive scientific discussion and positively affects the efficiency and dynamics of the citation of the published work (see The Effect of Open Access).